# Algorithm to find elements best fitting in a particular amount

I'm looking for an algorithm to solve the follwoing problem (I will explain it with an example):

Let say I have 10.000 \$ available amount and following costs I can finance using my amount:

cost 1: 1.000 \$

cost 2: 3.000 \$

cost 3: 4.000 \$

cost 4: 5.000 \$

The costs cannot be paid partially so either you pay the whole cost or you don't pay it at all. What I am looking for is an algorithm which helps me find the combination of costs which will not exceed available amount, but on the other side use the most part or the whole available amount.

In my example it would be: cost 1 + cost 3 + cost 4.

I would like also to add an parameter which determines how many costs can be maximally financed. If I say in my example that only two costs can be payed, cost 3 and cost 4 will be returned.

My approach would be to check all available combinations, sum them and pick the one which best uses the available amount. I wonder however if there is a simpliest way to find the optimal combination.

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This sounds like a variant of the knapsack problem. –  Oli Charlesworth Jul 29 '13 at 12:26
Seems to be a duplicate of stackoverflow.com/questions/16022205/… –  Heuster Jul 29 '13 at 12:43
@Oli Charlesworth: thank you for letting me know how this problem is called and for the provided link. Because I have always only a few costs the best way to find an optimal solution will be my original approach to go through all possible combinations and picking the best one (as also Mecki suggests). –  Okizb Jul 29 '13 at 13:12

This is a simple dynamic programming problem (A variation of Knapsack). State can be defined as [position][rest_amount][how_many_bills_can_be_paid]. A recursive solution below:

assuming `C`is the array of cost and `memo` is initialized with -1:

``````const int N = 10;    //number of notes to pay
int memo[N][M][K];   //remember to initialize it with -1

int func(int cur_index,int rest_amount,int K){

if(cur_index == N){
return 0;
}

int &ret = memo[cur_index][rest_amount][K];
if(ret != -1) return ret;    //memoization ensures we won't solve the same sub problem more than once
ret = 0;
if(rest_amount >= C[cur_index]  && K > 0 )
ret = func(cur_index+1,cost+C[cur_index],K-1);

ret = max(ret,func(cur_index+1,cost,K);

return ret;
}
``````
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I'm afraid I cannot understand your answer completely. Is it possible to "translate" it into PHP or java, maybe using my example as variables in your example? I would be very grateful for that. –  Okizb Jul 29 '13 at 15:58

I can't improve your solution for general data, however there are few improvements which can speed it up.

If total amount `N` is quite low there is simple dynamic solution:

``````setOfValues
put totalAmount to setOfValues
foreach cost do
foreach amount in setOfValues do
if (amount - cost) > 0 and not exists (amount - cost) in setOfValues
put (amount - cost) to setOfValues
get lowest setOfValues
``````

You can simple upgrade it to additional requirements (like up to `x` costs).

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Can you explain this a bit more? –  Phpdna Jul 29 '13 at 12:46
@Phpdna this is a similar algorithm as I gave a while ago to another question, but in a more obscure language. I think it's easier to follow there. –  Heuster Jul 29 '13 at 12:58
How much is the search space smaller? I have problems to understand it. –  Phpdna Jul 29 '13 at 13:03
@Phpdna Example: If there is amount 1000000 and 100 different costs my algorithm will do about 100kk operations instead of 2^100 (brutal algorithm) and find optimal solution. –  Ari Jul 29 '13 at 13:10
Your algorithm find the optimum in 100000 iteration? How much in percentage is the search space smaller? –  Phpdna Jul 29 '13 at 13:14

You can sort the list and pick the top until your budget is depleted. It's also used in bin-packing and it's guarantee to be within some range of the optimum.

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It won't find optimal value: lets say total amount is 10k and costs are 6k, 5k, 5k. Your soultion will choose 6k instead of 5k+5k. –  Ari Jul 29 '13 at 12:31
@Ari as Phpdna says, it's an approximation algorithm (from your example I would say it is a 2-approximation). However, dynamic programming can easily get you the optimal solution indeed. –  Heuster Jul 29 '13 at 12:40
I didn't say it's optimal I wrote it's within optimality. The search space is to big. The problem is also np hard. –  Phpdna Jul 29 '13 at 12:41

I designed an algorithm like this in java some weeks ago. I used a binary matrix with width N, where N is the number of different costs, and the height will be 2^N, giving us all possible combinations.

So the first item would refer to the lowest cost in your case. Here is an example with 1000, 3000, 4000. (You can expand this, but I just want to show you how I did.)

Width = N = 3

Height = 2^N = 8

``````0 0 0 = 0       +   0       +   0       =   0
1 0 0 = 1000    +   0       +   0       =   1000
0 1 0 = 0       +   3000    +   0       =   3000
1 1 0 = 1000    +   3000    +   0       =   4000
0 0 1 = 0       +   0       +   4000    =   4000
1 0 1 = 1000    +   0       +   4000    =   5000
0 1 1 = 0       +   3000    +   4000    =   7000
1 1 1 = 1000    +   3000    +   4000    =   8000
``````

I had a list with the costs in it. And as i went down the matrix row by row, i just checked the list where there was a 1 on the matrix. Since the costs are sorted, the row i find that is equal or greater than the total amount will be the lowest possible.

Tell me if you don't understand and i'll elaborate!

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These claims are a little too strong. The knapsack problem is weakly NP-hard, which means it has a polynomial solution in `n` (the number of items) and the value of `X` (the target value). For typical applications, dynamic programming is much more efficient than brute forcing. –  Heuster Jul 29 '13 at 14:10